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HUMAN GMP SYNTHETASE

An ample supply of nucleotides is essential for many life processes, including cell maturation, cell division and transmission of the genetic information. Indeed, nucleotides are the activated precursors of nucleic acids, but they also are major energy carriers, and precursors for the synthesis of nucleotide cofactors. Among these molecules is the guanosine monophosphate (GMP), also known as 5'-guanidylic acid or guanylic acid, a nucleotide that is used as a monomer in RNA. Like other nucleotides, GMP can be synthesized by 2 main pathways : de novo pathway and salvage pathway. De novo synthesis of nucleotide involves several enzymatic reaction and enzymes. Here, we will focus on the final step of the process, which is catalyzed by a glutamine amidotransferase called GMP synthetase (GMPS; E.C. 6.3.5.2). This enzyme belongs to the family of ligases, and catalyzes the conversion of xanthine monophosphate (XMP) to GMP in the presence of glutamine and ATP. ^[1]

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You may include any references to papers as in: the use of JSmol in Proteopedia ^[2] or to the article describing Jmol ^[3] to the rescue.

1 Structure
2 Function
3 Activation and inhibition
4 Disease
5 Relevance

Structure

GMP synthetase is a homodimer enzyme, in which each monomer is composed of 693 amino acids and weights 76,2 kDa. Each monomer is composed of two catalytic domains, encoded by a single gene: a N-terminal glutaminase domain (GATase domain), and a C-terminal synthetase domain.

Secondary structure of GMP synthetase

GTase domain:

The GATase domain, stretched from residue 27 to residue 216, is composed of a single structural domain. It is constituted of a central β-sheet surrounded by several α-helices. It contains the catalytic triad composed of residues Cys104, His190, and Glu192 where the ammonia is generated.

Synthetase domain:

The synthetase domain, stretched from residue 217 to residue 693, can be divided into three different sub-domains: an ATP pyrophosphatase domain (ATPPase domain) and two dimerization domains D1 and D2.

The ATPPase sub domain (residues 217-435) is composed of a 5-stranded parallele β-sheet-sandwiched between 9 α-helices.

The D1 sub-domain (residues 450-578), absent in bacteria and archaea, is involved in dimerization and substrate binding. It is constituted of an anti-parallel three-stranded β-sheet surrounded by five α-helices. The middle β-strand stretches out to form a β-hairpin (Ile514–Tyr528) which interacts with the XMP binding site of the other subunit of the dimer.

The second dimerization sub-domain, D2 (residues 579-693) is similar to the D1 sub-domain.

The active site in the C-terminal synthetase domain is located between the ATPPase sub-domain and the D2 sub-domain. When XMP is bound to it, it is allostericly regulated and covered by a lid motif (residues 368-408).

The synthetase domain binds several cofactors. Indeed, three sulphates ions are bound to the ATPPAse and D2 sub-domains. There are also Mg2+ and ATP which can bind.

Function

GMP synthetase is an enzyme belonging to the glutamine amidotransferases family, localized in the cytoplasm. These amidotransferases catalyse the amination of a wide range of molecules using the amide nitrogen of the side chain of glutamine. GMP synthetase is one of the three glutamine amidotransferases that plays a role in the de novo purine biosynthesis. Indeed, thanks to its bifunctional two domains, GMP synthetase catalyses the final step in the de novo synthesis of GMP from XMP in the presence of other cofactors including ATP, glutamine and water. The global reaction is summarized below:

ATP + XMP + L-glutamine + H2O --> AMP + diphosphate + GMP + L-glutamate.

Actually, the enzyme operates in two successive steps:

1) L-glutamine + H2O --> L-glutamate + NH3 2) ATP + XMP + NH3 --> AMP + pyrophosphate + GMP.

First, the glutaminase domain generates ammonia from glutamine-hydrolysis when L-glutamine binds to the catalytic triad. Then, an activation step prepares the XMP for amination. Indeed, GPM synthetase activates its XMP substrate by adenylylation on the xanthine C2 oxygen, which can then be primed for attack by a nitrogen nucleophile. In order to perform the second reaction, the glutamine-derived ammonia needs to be transferred to the XMP. This one is located in the active site of the synthetase domain, situated no far away from the catalytic triad. The ammonia translocation is enabled by a channel between the two active sites. This channel is formed thanks to a conformational change of the catalytic triad, further to its production. Thus, the activated XMP is aminated to produce GMP. Then, the GMP is released and will be used as a monomer in RNA.

Activation and inhibition

The presence of free Mg2+ is essential for activation of the GMP synthetase and a complex between ATP and Mg2+ can be formed but MgATP2− alone is not sufficient for catalysis. Moreover, the total chelation of free Mg2+ by ATP results of inactivation of the enzyme.

Inhibitor:

-Decoyinine is an uncompetitive inhibitor -Inorganic pyrophosphate is the most effective inhibitor and it is competitive toward ATP

-Psicofuranin is known to inhibit this enzyme.

-6-Diazo-5-oxo-L-norleucine (DON) is a glutamine antagonist

Disease

Relevance

References

↑ Oliver JC, Linger RS, Chittur SV, Davisson VJ. Substrate activation and conformational dynamics of guanosine 5'-monophosphate synthetase. Biochemistry. 2013 Aug 6;52(31):5225-35. doi: 10.1021/bi3017075. Epub 2013 Jul, 23. PMID:23841499 doi:http://dx.doi.org/10.1021/bi3017075
↑ Hanson, R. M., Prilusky, J., Renjian, Z., Nakane, T. and Sussman, J. L. (2013), JSmol and the Next-Generation Web-Based Representation of 3D Molecular Structure as Applied to Proteopedia. Isr. J. Chem., 53:207-216. doi:http://dx.doi.org/10.1002/ijch.201300024
↑ Herraez A. Biomolecules in the computer: Jmol to the rescue. Biochem Mol Biol Educ. 2006 Jul;34(4):255-61. doi: 10.1002/bmb.2006.494034042644. PMID:21638687 doi:10.1002/bmb.2006.494034042644

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Blandine Velut

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@@ Line 16: / Line 16: @@
 GMP synthetase is a homodimer enzyme, in which each monomer is composed of 693 amino acids and weights 76,2 kDa. Each monomer is composed of two catalytic domains, encoded by a single gene: a N-terminal glutaminase domain (GATase domain), and a C-terminal synthetase domain.
-[[Image:GMPs.jpg|thumb|center|300px|Secondary structure of GMP synthetase]]
+[[Image:GMPs.jpg|thumb|center|500px|Secondary structure of GMP synthetase]]
@@ Line 23: / Line 23: @@
 The GATase domain, stretched from residue 27 to residue 216, is composed of a single structural domain. It is constituted of a central β-sheet surrounded by several α-helices. It contains the catalytic triad composed of residues Cys104, His190, and Glu192  where the ammonia is generated.
-Synthetase domain:
+'''Synthetase domain:'''
 The synthetase domain, stretched from residue 217 to residue 693, can be divided into three different sub-domains: an ATP pyrophosphatase domain (ATPPase domain) and two dimerization domains D1 and D2.
@@ Line 39: / Line 39: @@
-GMP synthetase : What is it ? What are its functions? How it works?
+== Function ==
-GMP synthetase is an enzyme belonging to the glutamine amidotransferases family, localized in the cytoplasm. These amidotransferases catalyse the amination of a wide range of molecules using the amide nitrogen of the side chain of glutamine. GMP synthetase is one of the three glutamine amidotransferases that plays a role in the de novo purine biosynthesis. Indeed, thanks to its bifunctional two domains, GMP synthetase catalyses the final step in the de novo synthesis of GMP from XMP in the presence of other cofactors including ATP, glutamine and water. The global reaction is summarized below:
-ATP + XMP + L-glutamine + H2O  AMP + diphosphate + GMP + L-glutamate.
+GMP synthetase is an enzyme belonging to the glutamine amidotransferases family, localized in the cytoplasm. These amidotransferases catalyse the amination of a wide range of molecules using the amide nitrogen of the side chain of glutamine. GMP synthetase is one of the three glutamine amidotransferases that plays a role in the de novo purine biosynthesis. Indeed, thanks to its bifunctional two domains, GMP synthetase catalyses the final step in the de novo synthesis of GMP from XMP in the presence of other cofactors including ATP, glutamine and water. The global reaction is summarized below:
+ATP + XMP + L-glutamine + H2O --> AMP + diphosphate + GMP + L-glutamate.
 Actually, the enzyme operates in two successive steps:
-) L-glutamine + H2O   L-glutamate + NH3
+) L-glutamine + H2O  --> L-glutamate + NH3
-) ATP + XMP + NH3  AMP + pyrophosphate + GMP.
+) ATP + XMP + NH3 --> AMP + pyrophosphate + GMP.
-First, the glutaminase domain generates ammonia from glutamine-hydrolysis when L-glutamine binds to the catalytic triad. Then, an activation step prepares the XMP acceptor molecule for amination. Indeed, GPM synthetase activates its XMP substrate by adenylylation on the xanthine C2 oxygen, which can then be primed for attack by a nitrogen nucleophile. In order to perform the second reaction, the glutamine-derived ammonia needs to be transferred to the XMP. This one is located in the active site of the synthetase domain, situated no far away from the catalytic triad. The ammonia translocation is enabled by a channel between the two active sites. This channel is formed thanks to a conformational change of the catalytic triad, further to its production. Thus, the activated XMP is aminated to produce GMP. Then, the GMP is released and will be used as a monomer in RNA.
+First, the glutaminase domain generates ammonia from glutamine-hydrolysis when L-glutamine binds to the catalytic triad. Then, an activation step prepares the XMP for amination. Indeed, GPM synthetase activates its XMP substrate by adenylylation on the xanthine C2 oxygen, which can then be primed for attack by a nitrogen nucleophile. In order to perform the second reaction, the glutamine-derived ammonia needs to be transferred to the XMP. This one is located in the active site of the synthetase domain, situated no far away from the catalytic triad. The ammonia translocation is enabled by a channel between the two active sites. This channel is formed thanks to a conformational change of the catalytic triad, further to its production. Thus, the activated XMP is aminated to produce GMP. Then, the GMP is released and will be used as a monomer in RNA.
+== Activation and inhibition ==
-Activation et inhibition:
-The presence of free Mg2+ is essential for activation of the GMPs and a complex between ATP and Mg2+ can be formed but MgATP2− alone is not sufficient for catalysis. Moreover, the total chelation of free Mg2+ by ATP results of inactivation of the enzyme.
+The presence of free Mg2+ is essential for activation of the GMP synthetase and a complex between ATP and Mg2+ can be formed but MgATP2− alone is not sufficient for catalysis. Moreover, the total chelation of free Mg2+ by ATP results of inactivation of the enzyme.
-Inhibitor:
+'''Inhibitor:'''
 -Decoyinine is an uncompetitive inhibitor
 -Inorganic pyrophosphate is the most effective inhibitor and it is competitive toward ATP
@@ Line 63: / Line 69: @@
 == Relevance ==
-== Structural highlights ==

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Revision as of 15:37, 26 January 2017

2vxo

HUMAN GMP SYNTHETASE

Contents

Structure

Function

Activation and inhibition

Disease

Relevance

References

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